Seismic Response Analysis of Multi-Floored Grain Warehouses with Composite Structures Under Varying Grain-Loading Conditions

Seismic Response Analysis of Multi-Floored Grain Warehouses with Composite Structures Under Varying Grain-Loading Conditions

Multi-floored grain warehouses are widely used in China due to their efficient space utilization and high storage capacity. This study evaluates the seismic performance of such structures using a Composite Structure of Steel and Concrete (CSSC) system under various grain-loading conditions. A finite...

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Bibliographic Details
Main Authors: Zidan Li, Yonggang Ding, Jinquan Zhao, Chengzhou Guo, Zhenhua Xu, Guoqi Ren, Qikeng Xu, Qingjun Xian, Rongyu Yang
Format: Article
Language:English
Published: MDPI AG 2025-05-01
Series:Applied Sciences
Subjects:
multi-floored grain warehouse
pushover analysis
dynamic analysis
seismic performance
Online Access:https://www.mdpi.com/2076-3417/15/11/5970
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Summary:Multi-floored grain warehouses are widely used in China due to their efficient space utilization and high storage capacity. This study evaluates the seismic performance of such structures using a Composite Structure of Steel and Concrete (CSSC) system under various grain-loading conditions. A finite element model was developed in OpenSees based on actual loading scenarios, with both pushover and time history analyses conducted. Results show that the EEF condition (E = Empty, F = Full; top–middle–bottom = Empty–Empty–Full) leads to a 35.14% increase in peak base shear compared to the FEE condition (grain on the top floor only). Capacity spectrum analysis indicates that EEF provides higher initial stiffness and lower displacement across all performance points. Time history results reveal that configurations with lighter upper mass (EFF, EEE) are more prone to top-floor acceleration amplification, while FFF and FFE demonstrate more stable responses due to balanced mass distribution. The maximum inter-story drift consistently occurs at the second floor, with FFF and FFE showing the most significant deformation. All drift ratios meet code limits, confirming the safety and applicability of the CSSC system under various storage scenarios.
ISSN:2076-3417

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